KR102490943B1 - Gas adapter by blocking gas flow channel - Google Patents

Abstract

In the disclosed gas flow path blocking type gas adapter according to the present invention, an iso gas movement passage is formed to connect an iso gas cylinder at one end and a butane gas movement passage is formed to connect a butane gas cylinder to the other end, and the iso gas movement passage or the a body portion communicating with the butane gas passage and having a gas outlet through which the corresponding gas is discharged; an iso gas connection body connected to the iso gas moving passage in an airtight state, and having a pressing pin portion elastically supported so that the iso gas flows in while pressurized when the iso gas cylinder is connected to an inside of an end thereof; and a lock valve that manually or automatically opens and closes the butane gas passage while moving inside the body.
According to the present invention, when one of the butane gas cylinder or the iso gas cylinder is connected to the adapter, the gas flow path of the other side is manually or automatically blocked and the corresponding gas is discharged through the gas outlet, so that the butane gas or the iso gas is discharged through one adapter. There are optional effects available.

Description

Gas flow blocking type gas adapter {GAS ADAPTER BY BLOCKING GAS FLOW CHANNEL}

The present invention relates to a gas flow blocking type gas adapter, and more particularly, to an adapter capable of selectively using iso gas or butane gas through one adapter.

In general, various gas appliances that are easy to carry and move are equipped with a small portable butane gas container.

Portable butane gas containers can be divided into general butane gas containers that can be used in normal climates, such as at home or outdoors, and dome-type high-pressure butane gas containers that can be used in environments with different temperatures and atmospheric pressures, such as in the mountains. Gas appliances that can be used for both purposes are widely used regardless of the type of these gas containers.

A general butane gas container has a long cylindrical container shape, and a high-pressure butane gas container has a short dome shape to be distinguished from a general butane gas container.

On the other hand, since the biggest difference between the general request gas container and the high-pressure butane gas container is the structure and shape of the nozzle part for supplying gas, there is also a difference in the method of coupling with the gas appliance. That is, since the general butane gas container has a nozzle hole in the shape of a thin pipe, which is a gas supply means, protruding, the gas passage is opened by pressing the nozzle hole into the butane gas container to supply gas to the connected gas appliance. . However, the high-pressure butane gas container has a nozzle shape in which a relatively large diameter spiral part is formed to be screwed into a gas appliance unlike the nozzle hole of a general butane gas container, and the nozzle hole is bored in the center. On the other hand, on the outer circumferential surface of the nozzle hole, a cylindrical ejection pipe surrounding the nozzle hole is formed, respectively.

On the other hand, since the butane gas containers that can be connected and used are separated according to the type of gas appliance, it is impossible to connect because the connection means are different from each other, so that the butane gas container must be separately prepared to use it. To this end, a technology related to an adapter developed to connect and use high-pressure butane gas to a gas appliance using general request gas has been proposed in Korean Patent Registration No. 1098955.

However, since Patent Document 1 is limited to a function for connecting a general request gas to an object using high-pressure butane gas, there is a problem in that a separate adapter must be additionally purchased for the opposite function.

Korea Patent No. 1098955 (2011.12.20)

The present invention has been made in view of the above points, and the problem of the present invention is that when one of the butane gas cylinder or the iso gas cylinder is connected to the adapter, the other gas flow path is blocked and the corresponding gas is discharged through the gas outlet. An object of the present invention is to provide a shut-off type gas adapter with a gas oil that can selectively use butane gas or iso gas.

In order to achieve the above object, a gas flow path blocking type gas adapter according to the present invention has an iso gas flow path formed at one end to connect an iso gas cylinder and a butane gas flow path formed at the other end to connect a butane gas cylinder. a body portion communicating with the gas flow passage or the butane gas flow passage to form a gas outlet through which the corresponding gas is discharged; an iso gas connection body connected to the iso gas moving passage in an airtight state, and having a pressing pin portion elastically supported so that the iso gas flows in while pressurized when the iso gas cylinder is connected to an inside of an end thereof; and a locking valve that manually or automatically opens and closes the butane gas passage while moving inside the body.

The locking valve protrudes and descends in the transverse direction from the valve moving hole of the body, which is positioned on the same line as the butane gas moving passage, and a part is exposed to the outside of the valve moving hole and the remaining part is airtight inside the valve moving hole. a pressing portion positioned in this maintained state; and an extension part extending from an end of the pressing part and having an end in close contact with or separated from the butane gas movement passage.

The locking valve is formed in a direction orthogonal to the butane gas moving passage and protrudes and descends in the longitudinal direction from the valve moving hole of the body part communicating with the gas outlet, and is positioned in the valve moving hole in a state in which airtightness is maintained so that the gas a valve body closely attached to or separated from an end of the valve moving hole at the outlet side; and an elastic part providing an elastic force so that the valve body always moves downward.

The valve body may be moved up and down by a valve lifting groove formed on one side of an upper surface of the rotatable isogas connection body at the bottom of the body.

The valve body is raised when the lower part is located outside the valve lifting groove by rotating the iso gas connection body in one direction for the use of iso gas, and the lower part is raised by rotating the iso gas connection body in the other direction for the use of butane gas. When located inside the valve lifting groove, it can be lowered.

The butane gas moving passage may be connected to the butane gas cylinder through a hose or directly connected to the butane gas cylinder.

According to the present invention, when one of the butane gas cylinder or the iso gas cylinder is connected to the adapter, the gas flow path of the other side is manually or automatically blocked and the corresponding gas is discharged through the gas outlet, so that the butane gas or the iso gas is discharged through one adapter. There are optional effects available.

1 is an exploded perspective view showing a state in which an iso gas cylinder is separated from a gas flow path blocking type gas adapter according to a first embodiment of the present invention.
2 is a cross-sectional view showing gas flow when an isogas cylinder is connected to a gas flow path blocking type gas adapter according to a first embodiment of the present invention.
3 is a cross-sectional view showing gas flow when a butane gas cylinder is connected to a gas flow path blocking type gas adapter according to the first embodiment of the present invention.
4 is an exploded perspective view showing a state in which an iso gas cylinder is separated from a gas flow path blocking type gas adapter according to a second embodiment of the present invention.
5 is a cross-sectional view showing gas flow when an isogas cylinder is connected to a gas flow path blocking type gas adapter according to a second embodiment of the present invention.
6 is a cross-sectional view showing gas flow when a butane gas cylinder is connected to a gas flow path blocking type gas adapter according to a second embodiment of the present invention.
7 is a perspective view showing a state in which a lock valve is lifted in a gas flow path blocking type gas adapter according to a second embodiment of the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a gas multi-adapter according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a state in which an isogas cylinder is separated from a gas flow path blocking type gas adapter according to a first embodiment of the present invention, and FIG. 2 is a gas flow path blocking type gas adapter according to a first embodiment of the present invention. Figure 3 is a cross-sectional view showing the gas flow when the butane gas cylinder is connected to the gas flow path blocking type gas adapter according to the first embodiment of the present invention, Figure 4 is a cross-sectional view showing the gas flow when the iso gas cylinder is connected to An exploded perspective view showing a state in which the isogas cylinder is separated from the gas flow path blocking type gas adapter according to the second embodiment of the present invention, and FIG. 5 is an isogas cylinder in the gas flow path blocking type gas adapter according to the second embodiment of the present invention. Figure 6 is a cross-sectional view showing the gas flow when the butane gas cylinder is connected to the gas flow path blocking type gas adapter according to the second embodiment of the present invention, Figure 7 is the second cross-sectional view of the present invention It is a perspective view showing a state in which the lock valve is lifted in the gas flow path blocking type gas adapter according to the embodiment.

1 to 3, the gas flow path blocking type gas adapter 100 according to the first embodiment of the present invention includes a body portion 110, an isogas connection body 120, a pressure pin portion 130, and a locking valve. (140).

Here, referring to FIG. 1, the iso gas cylinder 10 has a spiral portion 12 of a relatively large diameter so that the nozzle shape is screwed with a gas appliance unlike the nozzle hole of the butane gas container, and the spiral portion 12 is formed in the center of the spiral portion 12. The nozzle hole 14 has a pierced shape. A rim 16 is formed outside the nozzle hole 14 .

As shown in FIGS. 1 to 3, the body portion 110 has an iso gas movement passage 112 penetrating in the longitudinal direction to the gas outlet 118 on the upper surface so that the iso gas cylinder 10 is connected to the bottom surface. The butane gas passage 114 is formed through the side in the transverse direction so that the butane gas passage 114 communicates with the iso gas passage 112 so that the butane gas cylinder (not shown in the figure) is connected, and the valve on the other side of which the lock valve 140 is located The moving hole 116 is formed on the same horizontal line as the center of the butane gas moving passage 114.

The isogas movement passage 112 is formed to have an inner diameter larger than the outer diameter of the extension part 144 of the lock valve 140 so as not to be affected by gas movement by the extension part 144 .

Here, in the butane gas passage 114, a first stepped hole 114a, which is a stepped hole having a reduced diameter, is formed at the intersection of the butane gas passage 114 and the iso gas passage 112, and the first stepped hole When the inclined surface 144a formed on the extension part 144 of the lock valve 140 comes into contact with (114a), the butane gas movement passage 114 is closed, and the inclined surface 144a is separated from the first stepped hole 114a. When this is done, the butane gas passage 114 and the iso gas passage 112 are in communication.

On the other hand, the butane gas passage 114 is formed with a butane gas connection part 115 at an end so that the butane gas cylinder is connected through the hose 115a, and although not shown in the drawing, the butane gas cylinder can be directly connected. In this way, when the butane gas cylinder is directly connected to the butane gas connection part 115, the pressure pin part corresponding to the pressure pin part 130 located inside the iso gas connection body 120 is located in an elastically supported state, so that the butane gas cylinder When connected, it is possible to pressurize the nozzle hole formed in the shape of a pipe.

In the valve moving hole 116, a second stepped hole 116a having a reduced diameter is formed at the intersection of the valve moving hole 116 and the isogas moving passage 112, and the extension part 144 of the lock valve 140 ) moves in the transverse direction.

In addition, the valve moving hole 116 has a groove formed along the inner circumferential surface so that the third packing P3 is provided, so that even if the lock valve 140 protrudes and descends through the third packing P3 provided in the groove, the lock valve 140 ) is kept confidential.

Furthermore, the gas outlet 118 communicates with the iso gas passage 112 or the butane gas passage 114 so that the iso gas or butane gas is selectively discharged.

As shown in FIGS. 1 to 3, the iso gas connection body 120 is connected to the iso gas passage 112 formed on the bottom of the body 110, and the iso gas passage 112 is connected to the bottom of the iso gas passage 112. The connection part 122 is connected.

Furthermore, the isogas connection body 120 has an annular groove formed on the upper surface, and the first packing P1 is embedded in the groove to maintain airtightness with the lower surface of the body portion 110 .

The isogas connecting portion 122 has an isogas fastening hole 122a formed on the opened lower inner circumferential surface so as to be spirally engaged with the spiral portion 12 of the isogas cylinder 10, and an isogas movement passage ( 112), a second stepped hole 122b with a reduced diameter is formed, and a moving hole 122b' in which the support part 124 is located is formed in the longitudinal direction from the second stepped hole 122b to the upper surface.

In addition, the support part 124 having the passage hole 124a formed in the longitudinal direction on the upper side of the second stepped hole 122b is positioned to communicate with the lower end of the isogas movement passage 112, and the first lower side of the support part 124 The pressing pin unit 130 is provided to be able to move up and down in the second step hole 122b.

On the other hand, as shown in FIGS. 1 to 3 , the pressure pin unit 130 is provided in the form of a flange larger than the inner diameter of the second stepped hole 122b at the top, and when in close contact with the second stepped hole 122b, the maximum descending position. will be limited

In addition, the first elastic part 126 is provided between the lower part of the support part 124 and the upper surface of the pressure pin part 130 so that the spiral part 12 presses when the iso gas cylinder 10 is fastened to the iso gas fastening hole 122a. When the isogas cylinder 10 is separated from the isogas fastening hole 122a, the first elastic part 126 is stretched.

In this way, when the pressure pin part 130 is raised by the fastening of the iso gas cylinder 10, the second stepped hole 122b, the through hole 124a of the support part 124, and the iso gas passage 112 communicate with each other, Gas is directed to the gas outlet 118 . Conversely, when the pressure pin unit 130 descends due to separation of the isogas cylinder 10, the second stepped hole 122b is closed and the isogas is not introduced.

As shown in FIGS. 2 and 3 , the lock valve 140 is moved in the forward and backward lateral direction by the user inside the valve moving hole 116 of the body 110 and manually moves the butane gas passage 114. open and close by

At this time, the locking valve 140 is partially exposed to the outside of the valve moving hole 116, and the other part has a pressurizing portion 142 positioned in an airtight state inside the valve moving hole 116, and pressurizing It extends from the end of the portion 142 and includes an extension portion 144 whose end is in close contact with or separated from the edge of the first stepped hole 114a.

At this time, the end exposed to the outside of the valve moving hole 116 among the pressing parts 142 has a larger diameter than the end located inside the valve moving hole 116 .

Meanwhile, a groove is formed along the outer circumferential surface of an end of the pressing portion 142 located inside the valve moving hole 116, and the fourth packing P4 is positioned in the groove.

Furthermore, the extension part 144 has a tapered inclined surface 144a formed at an end adjacent to the first stepped hole 114a, and the second packing P2 is coupled along the inclined surface 144a.

The inclined surface 144a is formed so that the second packing P2 provided on the inclined surface 144a penetrates the first stepped hole 114a and adheres to the step of the first stepped hole 114a.

In this way, the operation process of the gas flow path blocking type gas adapter 100 according to the first embodiment of the present invention will be described.

First, referring to FIG. 2, a process of supplying iso gas by connecting the iso gas cylinder 10 to the gas flow path blocking type gas adapter 100 according to the first embodiment of the present invention will be described, the locking valve ( 140) in the direction of the butane gas passage 114, so that the second packing P2 provided on the inclined surface 144a of the lock valve 140 connects the butane gas passage 114 and the iso gas passage 112. The first stepped hole 114a formed at the intersection is closed to prevent isogas from flowing out.

In this way, since the lock valve 140 closes the first stepped hole 114a, the butane gas passage 114 remains closed.

Next, when the spiral portion 12 of the iso gas cylinder 10 is fastened to the iso gas fastening hole 122a of the iso gas connection body 120 provided on the bottom surface of the body portion 110, the iso gas cylinder 10 While the spiral portion 12 of the elevates the pressing pin portion 130, the second stepped hole 122b is opened.

Next, the gas of the isogas cylinder 10 passes through the open second stepped hole 122b through the passage hole 124a of the support part 124, the isogas movement passage 112 and the gas outlet 118, and passes through the isogas gas outlet 118. is supplied to a gas appliance (not shown in the drawing).

Second, referring to FIG. 3, a process of supplying butane gas by connecting a butane gas cylinder to the gas flow path blocking type gas adapter 100 according to the first embodiment of the present invention will be described. The second packing P2 provided on the inclined surface 144a of the lock valve 140 by pulling the butane gas passage 114 in the opposite direction is at the intersection of the butane gas passage 114 and the iso gas passage 112. The formed first stepped hole 114a is opened.

At this time, the pressure pin part 130 located in the second stepped hole 122b of the isogas connection part 122 is a first elastic part 126 provided between the lower part of the support part 124 and the upper surface of the pressure pin part 130 Since the flange part closes the second stepped hole 122b by descending due to the elastic force of the isogas flow passage 112, butane gas does not leak while maintaining the closed state.

Next, when the inclined surface 144a of the lock valve 140 is separated from the first stepped hole 114a by the retreat of the lock valve 140, the butane gas passage 114 and the iso gas passage 112 communicate with each other. While doing so, butane gas is supplied to a gas appliance (not shown in the drawing) through the gas outlet 118.

4 to 7, the gas flow path blocking type gas adapter 200 according to the second embodiment of the present invention includes a body portion 210, an isogas connection body 220, a pressure pin portion 230, and a locking valve. (240).

As shown in FIGS. 4 to 6, the body portion 210 has an isogas movement passage 212 penetrating in the longitudinal direction to the gas outlet 218 on the upper surface so that the isogas cylinder 10 is connected to the bottom surface. The butane gas passage 214 is formed in the transverse direction without communicating with the iso gas passage 212 so that the butane gas cylinder (not shown) is connected to the side, and is locked at the end of the butane gas passage 214 A valve moving hole 216 in which the valve 240 is positioned is formed in the longitudinal direction.

Here, the valve moving hole 216 has a first stepped hole 214a formed at an upper portion of the lowered diameter, and an inclined surface 242a formed on the top of the valve body 241 of the lock valve 240 in the first stepped hole 214a. When this contact occurs, the butane gas passage 214 is closed, and when the inclined surface 242a is separated from the first stepped hole 214a, the butane gas passage 214 and the iso gas passage 212 communicate.

Furthermore, the valve moving hole 216 is communicated with the gas outlet 218 on the upper side of the isogas moving passage 212 through an inclined connection hole 214b.

Meanwhile, as in the previous embodiment, the butane gas passage 214 is formed with a butane gas connection part 215 at an end such that the butane gas cylinder is connected through a hose, and in addition, the butane gas cylinder can be directly connected.

Furthermore, the gas outlet 218 communicates with the iso gas passage 212 or the butane gas passage 214 so that the iso gas or butane gas is selectively discharged.

As shown in FIGS. 4 to 6, the isogas connection body 220 is rotatably provided on the bottom of the body 210 and is connected to the isogas passage 212 formed on the bottom of the body 210. , The isogas connection part 222 is connected to the lower part of the isogas moving passage 212.

At this time, since the isogas connection body 220 is rotatably provided, the upper surface of the flange portion of the support part 224, the lower surface of the body portion 210, and the upper surface of the isogas connection part 222 are respectively provided through the fifth packing P5. ensure confidentiality is maintained.

Unlike this, the isogas connection body 220 has an annular groove formed on the upper surface, and packing (not shown in the drawings) can be embedded in the groove to maintain airtightness with the bottom surface of the body portion 210.

The isogas connection part 222 has an isogas fastening hole 222a formed on the opened lower inner circumferential surface so as to be screwed with the spiral portion 12 of the isogas cylinder 10, and an isogas movement passage ( 212), a second stepped hole 222b with a reduced diameter is formed, and a moving hole 222b' in which the support part 224 is located is formed in the longitudinal direction from the second stepped hole 222b to the upper surface.

In addition, a support portion 224 having a passage hole 224a formed in the longitudinal direction above the second stepped hole 222b is positioned to communicate with the lower end of the isogas movement passage 212, and is located below the support portion 224. The pressure pin unit 230 is provided to be able to move up and down in the second step hole 222b.

In addition, a valve lifting groove 226 is formed on the lower side of the valve body 241 of the locking valve 240 on the upper surface of the isogas connection body 220.

The valve lifting groove 226 is formed on one side of the upper surface of the isogas connection body 220 to lift the valve body 241 of the lock valve 240.

That is, when the isogas connection body 220 is rotated in one direction for the use of isogas and the lower portion of the valve body 241 is positioned on the upper surface of the isogas connection body 220 outside the valve lifting groove 226, the valve body ( 241) is raised (see FIG. 7 (a)), and the isogas connection body 220 is rotated in the other direction for the use of butane gas so that the valve body 241 located on the upper surface of the isogas connection body 220 When the lower part is positioned on the inner bottom surface of the valve lifting groove 226, the valve body 241 is lowered (see FIG. 7(b)).

In addition, the valve elevating groove 226 has an inclined surface formed in the direction in which the valve body 241 moves while in contact with it, and gradually rises or descends along the inclined surface.

On the other hand, since the pressure pin unit 230 has the same structure and function as that of the previous embodiment, a detailed description thereof will be omitted.

In addition, a first elastic part 226 is provided between the lower part of the support part 224 and the upper surface of the pressure pin part 230 so that the spiral part 12 presses when the iso gas cylinder 10 is fastened to the iso gas fastening hole 222a. When the isogas cylinder 10 is separated from the isogas fastening hole 222a, the first elastic part 226 is stretched.

As shown in FIGS. 5 and 6 , the locking valve 240 is moved in the vertical direction by the rotation of the isogas connection body 220 inside the valve moving hole 216 of the body 210 while releasing butane gas. The moving passage 214 is automatically opened and closed.

At this time, the locking valve 240 is located in the airtight state of the valve moving hole 216, and the valve body 241 closely attached to or separated from the top of the valve moving hole 216 and the valve body 241 are always It includes an elastic part 244 that provides an elastic force to move downward.

In the valve body 241, an inclined surface 242a of a tapered structure is formed on the upper portion adjacent to the first stepped hole 214a of the valve moving hole 216, and the second packing P2 is formed along the circumference of the inclined surface 242a. this is combined

At this time, the lower part of the valve body 241 is formed in a hemispherical shape, a stepped part 242b is formed in the middle part, and an inclined surface 232a is formed in the upper part.

The inclined surface 242a is formed so that the second packing P2 provided on the inclined surface 242a penetrates the first stepped hole 214a and adheres to the step of the first stepped hole 214a.

Furthermore, the valve body 241 has a groove formed along the lower outer circumferential surface so that the fourth packing P4 is provided, so that the lock valve 240 protrudes and descends through the fourth packing P4 provided in the groove. ) is kept confidential.

The elastic part 244 is provided so that both ends are supported between the upper part of the valve moving hole 216 and the stepped part 242b formed on the lower side of the valve body 241, by one-way rotation of the isogas connecting body 220. When the valve body 241 rises, it is compressed, and when the lower part of the valve body 241 is positioned on the bottom surface of the valve lifting groove 226 by the rotation of the isogas connection body 220 in the other direction, it expands.

In this way, the operation process of the gas flow path blocking type gas adapter 200 according to the second embodiment of the present invention will be described.

First, referring to FIG. 5, a process of supplying iso gas by connecting the iso gas cylinder 10 to the gas flow path blocking type gas adapter 200 according to the second embodiment of the present invention will be described, the locking valve ( 240), the lower part of the valve body 241 is located on the upper surface of the isogas connection body 220 rather than the bottom surface of the valve lifting groove 226, and the inclined surface 242a of the valve body 241 is positioned on the first stepped hole 214a. ) to prevent isogas from escaping.

In this way, since the valve body 241 of the lock valve 240 closes the first stepped hole 214a, the butane gas passage 214 remains closed.

Next, when the spiral portion 12 of the iso gas cylinder 10 is fastened to the iso gas fastening hole 222a of the iso gas connection body 220 provided on the bottom surface of the body portion 210, the iso gas cylinder 10 While the spiral portion 12 of the elevates the pressing pin portion 230, the second stepped hole 222b is opened.

Next, the gas of the isogas cylinder 10 passes through the open second stepped hole 222b through the passage hole 224a of the support part 224, the isogas movement passage 212 and the gas outlet 218, and passes through the isogas gas outlet 218. is supplied to a gas appliance (not shown in the drawing).

Second, referring to FIG. 6, a process of supplying butane gas by connecting a butane gas cylinder to the gas flow path blocking gas adapter 200 according to the second embodiment of the present invention will be described, isogas connecting body 220 ) is rotated so that the lower part of the valve body 241 of the locking valve 240 is positioned on the bottom surface of the valve lifting groove 226 rather than the upper surface of the isogas connection body 220, while the inclined surface of the valve body 241 ( 242a) opens the first stepped hole 214a.

At this time, the pressure pin part 230 located in the second stepped hole 222b of the isogas connection part 222 is a first elastic part 226 provided between the lower part of the support part 224 and the upper surface of the pressure pin part 230 Since the flange part closes the second stepped hole 222b by descending due to the elastic force of the isogas flow passage 212, butane gas does not leak while maintaining the closed state.

Next, when the inclined surface 242a formed on the upper part of the valve body 241 of the lock valve 140 is separated from the first stepped hole 214a by the descent of the lock valve 240, the butane gas movement passage 214 and the iso While the gas movement passage 212 communicates with each other through the connection hole 214b, butane gas is supplied to a gas appliance (not shown) through the gas outlet 218.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting.

100, 200: gas flow path blocking type gas adapter 110, 210: body part
112, 212: isogas passage 114, 214: butane gas passage
116, 216: valve moving hole 118, 218: gas outlet
120, 220: isogas connection body 122, 222: isogas connection
126, 226: first elastic part 130, 230: pressing pin part
140, 240: lock valve 142: pressurization part
144: extension part 241: valve body
244: second elastic part

Claims (6)

An iso gas passage is formed at one end to connect the iso gas cylinder, and a butane gas passage is formed to connect the butane gas cylinder to the other end, and the gas is communicated with the iso gas passage or the butane gas passage to discharge the corresponding gas. A body portion in which a discharge port is formed;
an iso gas connection body connected to the iso gas moving passage in an airtight state, and having a pressing pin portion elastically supported so that the iso gas flows in while pressurized when the iso gas cylinder is connected to an inside of an end thereof; and
A lock valve that opens and closes the butane gas passage manually or automatically while moving inside the body,
The lock valve
It is formed in a direction orthogonal to the butane gas movement passage and emerges in the longitudinal direction from the valve movement hole of the body portion communicating with the gas outlet,
a valve body located in the airtight state of the valve moving hole and in close contact with or separated from an end of the valve moving hole at the gas outlet side; and
A gas flow path blocking type gas adapter comprising an elastic part providing an elastic force so that the valve body always moves downward.
delete delete According to claim 1,
The gas flow blocking type gas adapter, characterized in that the valve body is elevated by a valve lifting groove formed on one side of the upper surface of the isogas connection body rotatable in the lower part of the body.
According to claim 4,
The valve body is raised when the lower part is located outside the valve lifting groove by rotating the iso gas connection body in one direction for the use of iso gas, and the lower part is raised by rotating the iso gas connection body in the other direction for the use of butane gas. A gas flow path blocking type gas adapter, characterized in that lowered when located inside the valve lifting groove.
According to claim 1,
The gas flow path blocking type gas adapter, characterized in that the butane gas moving passage is connected to the butane gas cylinder through a hose or directly connected to the butane gas cylinder.

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